TY - JOUR
T1 - The Faroe-Shetland Gateway: Late Quaternary water mass exchange between the Nordic seas and the northeastern Atlantic
AU - Rasmussen, T.L.
AU - Bäckstrom, D.
AU - Heinemeier, J.
AU - Klitgaard-Kristensen, D.
AU - Knutz, P.C.
AU - Kuijpers, A.
AU - Lassen, S.
AU - Thomsen, E.
AU - Troelstra, S.R.
AU - van Weering, T.C.E.
N1 - Funding Information:
This study was part of the ENAM I and ENAM II projects 1993–1999 under the EU MAST II Program. T.L.R. was funded by the Carlsberg Foundation 1993–1994 and 1997–1998 and by the University of Copenhagen in 1995–1996. From 1999 the studies were continued with support from the Danish Natural Sciences Research Council (under the North Atlantic Programme, the LINK-Project), and the University of Lund. Work on ENAM cores was performed at the Netherlands Institute for Sea Research 1993–1994, the University of Copenhagen 1995–1996, Woods Hole Oceanographic Institution 1997–1998, and the University of Lund from 1999 onwards. I warmly thank colleagues and staff at all these Institutions for help and support and good co-operation over the years. Alice Rosenstand, GEUS, is thanked for the help with the maps for this publication and Ian Snowball, Lund University, for correcting the English language. D. Oppo, and D. Ostermann, both WHOI, are warmly thanked for the isotope work on ENAM33. E. Thomas and two anonymous reviewers are thanked for helpful reviews and suggestions.
PY - 2002/8/15
Y1 - 2002/8/15
N2 - Thirteen piston and gravity cores from the Faroe-Shetland area were investigated for their planktic and benthic foraminiferal and oxygen isotopic distributions. Eight time-slices between 18 ka BP and the present were reconstructed to study variations in surface and deep water exchange between the SE Norwegian Sea and the northeast Atlantic Ocean. Today, a relatively strong northward flow of warm North Atlantic surface water is counterbalanced by a southward outflow of newly convected cold bottom water, the Norwegian Sea Overflow Water. During the last glacial maximum at 18 ka BP both the surface and bottom flows were slow and the climate conditions were Arctic. The convection north of the Faroe area was weak and unstable. The first indication of the deglaciation is a decrease in the planktic oxygen isotope values discernible southwest of the Faroe Islands at 15.5 ka BP. The deglaciation proceeded northeast and eastward synchronous with a gradual intensification of northward flowing warmer Atlantic Intermediate Water along the sea bottom. Meltwater fluxes increased between 14 and 13 ka BP producing cold surface waters, and the climatic cooling was extreme. There was no southward overflow of cold bottom water during this time period and the exchange of water masses between the Nordic seas and the North Atlantic Ocean was essentially reversed, i.e. estuarine. During the Bølling Interstadial at 12.5 ka BP northward flowing warm surface water was present to the east of the Faroe-Shetland Channel, wedged below a tongue of polar water spreading from the northwest and reaching into the Faroe-Shetland Channel. Convection in the Nordic seas and overflow of cold deep water started during the Bølling Interstadial. The polar water spread more eastward and southward during the following cold spell, the Younger Dryas, around 10.3 ka BP. The polar water was overlying the warmer, but more saline Atlantic water, which flowed northward below the cold surface water. The overflow of cold bottom water was supposedly only slightly weaker than during the Bølling Interstadial. Strong inflow of warm surface water took place during the Early Holocene at 9.5 ka BP and relatively dense cold water flowed southward along the bottom. The rate of water mass exchange reached a maximum at 6.5 ka BP, when both the inflow of warm Atlantic surface water and the outflow of cold dense bottom water appear to have been stronger than today.
AB - Thirteen piston and gravity cores from the Faroe-Shetland area were investigated for their planktic and benthic foraminiferal and oxygen isotopic distributions. Eight time-slices between 18 ka BP and the present were reconstructed to study variations in surface and deep water exchange between the SE Norwegian Sea and the northeast Atlantic Ocean. Today, a relatively strong northward flow of warm North Atlantic surface water is counterbalanced by a southward outflow of newly convected cold bottom water, the Norwegian Sea Overflow Water. During the last glacial maximum at 18 ka BP both the surface and bottom flows were slow and the climate conditions were Arctic. The convection north of the Faroe area was weak and unstable. The first indication of the deglaciation is a decrease in the planktic oxygen isotope values discernible southwest of the Faroe Islands at 15.5 ka BP. The deglaciation proceeded northeast and eastward synchronous with a gradual intensification of northward flowing warmer Atlantic Intermediate Water along the sea bottom. Meltwater fluxes increased between 14 and 13 ka BP producing cold surface waters, and the climatic cooling was extreme. There was no southward overflow of cold bottom water during this time period and the exchange of water masses between the Nordic seas and the North Atlantic Ocean was essentially reversed, i.e. estuarine. During the Bølling Interstadial at 12.5 ka BP northward flowing warm surface water was present to the east of the Faroe-Shetland Channel, wedged below a tongue of polar water spreading from the northwest and reaching into the Faroe-Shetland Channel. Convection in the Nordic seas and overflow of cold deep water started during the Bølling Interstadial. The polar water spread more eastward and southward during the following cold spell, the Younger Dryas, around 10.3 ka BP. The polar water was overlying the warmer, but more saline Atlantic water, which flowed northward below the cold surface water. The overflow of cold bottom water was supposedly only slightly weaker than during the Bølling Interstadial. Strong inflow of warm surface water took place during the Early Holocene at 9.5 ka BP and relatively dense cold water flowed southward along the bottom. The rate of water mass exchange reached a maximum at 6.5 ka BP, when both the inflow of warm Atlantic surface water and the outflow of cold dense bottom water appear to have been stronger than today.
KW - Faroe-Shetland Channel
KW - Foraminifera
KW - Late Quaternary
KW - North Atlantic
KW - Thermohaline circulation
UR - http://www.scopus.com/inward/record.url?scp=0037102516&partnerID=8YFLogxK
U2 - 10.1016/S0025-3227(02)00280-3
DO - 10.1016/S0025-3227(02)00280-3
M3 - Article
SN - 0025-3227
VL - 188
SP - 165
EP - 192
JO - Marine Geology
JF - Marine Geology
IS - 1-2
ER -